KR102657426B1 - waterproof sheet comprising pulp recycled from waste diaper - Google Patents

Abstract

The waterproof sheet recycled from pulp recovered from discarded diapers according to the present invention includes: a base layer made of synthetic resin provided to form a planar structure; an upper reinforcement layer provided on top of the base layer; a lower reinforcement layer provided below the base layer; And, a finishing protective layer provided on the upper part of the upper reinforcement layer and the lower part of the lower reinforcement layer, respectively,
The base layer is made of non-woven fabric, and the upper and lower reinforcement layers are made of polymer-modified asphalt and synthetic resin and pulp obtained by crushing the shell portion of a waste diaper.
As a result, synthetic resin and pulp recovered from waste diapers are applied to the waterproof sheet, thereby improving heat resistance due to pulp components, minimizing thermal deformation, strengthening toughness, improving resistance to tensile force, and increasing durability. By providing waterproof sheets used in various places such as highways, tunnels, building underground parking lots, and building rooftops at a much lower cost, we can minimize the indiscriminate incineration of used diapers and contribute to saving resources and environmental conservation by collecting waste diapers. We can provide waterproof sheets made from recycled pulp.

Description

Waterproof sheet comprising pulp recycled from waste diaper}

The present invention relates to a waterproof sheet recycled from pulp recovered from waste diapers. More specifically, by applying synthetic resin and pulp recovered from waste diapers to the waterproof sheet, heat resistance is improved by the pulp components and thermal deformation is minimized. The toughness is strengthened, the resistance to tensile force is excellent, and durability can be increased. Waterproof sheets used in various places such as highways, tunnels, building underground parking lots, and building rooftops are provided at a much lower cost, preventing indiscriminate incineration of waste diapers. This is about a waterproof sheet made from recycled pulp recovered from discarded diapers, which can minimize the use of waste and contribute to saving resources and preserving the environment.

In modern society, as interest in hygiene increases, the use of various sanitary products is rapidly increasing, and various environmental pollution problems are being highlighted. Among them, it is known that one infant uses about 5.87 disposable paper diapers, and about 5,000 diapers are used when an infant up to 25 months old uses diapers.

In addition, in the case of Seoul, it is known that 1.8 million disposable diapers are used per day, and in Korea as a whole, about 2.4 billion diapers are consumed. This is equivalent to consuming 189.7 kg of wood and 109 kg of fossil fuel per infant. Furthermore, this is equivalent to consuming 722 trees, and if all infants in the country used diapers, forest resources equivalent to half of Jeju Island would be damaged every year.

In addition to the above problems, the problem of disposing of waste diapers also has a very negative environmental impact. Despite the continued policy of suppressing the use of disposable paper diapers, there is almost no decrease in the amount of disposable paper diapers used, and all used diapers are landfilled or incinerated. Not only do they not decompose for more than 100 years when landfilled, but they also release harmful substances such as dioxin when incinerated. Due to problems such as the occurrence of , interest in diaper recycling is rapidly increasing.

Meanwhile, Korean Patent No. 10-1173181 discloses a waterproof sheet equipped with a non-woven fabric for preventing separation, and the waterproof sheet includes a first layer (11) made of natural fiber or synthetic fiber, and a PE or PP resin melted with heat. It consists of a second layer (12) made in a liquid form and uniformly sprayed on the lower part of the first layer (11) and integrated with the first layer.

However, since the above-mentioned conventional waterproof sheets must be manufactured from new ones rather than recycled PE or PP, the production cost increases, and it is difficult to expect them to contribute to saving resources and preserving the environment.

In particular, conventional waterproof sheets have problems in that they are vulnerable to thermal deformation and do not have high toughness, so they can be easily deformed or damaged by external forces.

Republic of Korea Patent Registration No. 10-1173181 (registered on August 6, 2012)

The purpose of the present invention is to apply synthetic resin and pulp recovered from waste diapers to waterproof sheets, so that heat resistance is improved by the pulp components, thereby minimizing thermal deformation, strengthening toughness, improving resistance to tensile force, and increasing durability. We can minimize the indiscriminate incineration of waste diapers and contribute to saving resources and environmental preservation by providing waterproof sheets that are used in various places such as highways, tunnels, building underground parking lots, and building rooftops at a much lower cost. The goal is to provide waterproof sheets made from recycled pulp recovered from diapers.

In order to achieve the above object, the waterproof sheet recycled from pulp recovered from waste diapers according to the present invention includes: a base layer made of synthetic resin provided to form a planar structure; an upper reinforcement layer provided on top of the base layer; a lower reinforcement layer provided below the base layer; And, a finishing protective layer provided on the upper part of the upper reinforcement layer and the lower part of the lower reinforcement layer, respectively,

The base layer is made of non-woven fabric, and the upper and lower reinforcement layers are made of polymer-modified asphalt and synthetic resin and pulp obtained by crushing the shell portion of a waste diaper.

Here, the upper reinforcement layer and the lower reinforcement layer are made of a material obtained by melting and mixing 50% by weight of polymer-modified asphalt and 50% by weight of pulp and synthetic resin obtained by crushing the shell portion of a waste diaper, and are laminated on the top and bottom of the base layer. It is desirable.

In addition, the synthetic resin components of the upper reinforcing layer and the lower reinforcing layer include polyethylene (PE) and polypropylene (PP) obtained by crushing the shell portion of the waste diaper, and the pulp component of the upper reinforcing layer and the lower reinforcing layer are obtained from the shell portion of the waste diaper. It is preferable to include 10 to 20% by weight of pulp remaining by hot melt fusion even after crushing.

According to the present invention, synthetic resin and pulp recovered from waste diapers are applied to waterproof sheets, so that heat resistance is improved by pulp components to minimize thermal deformation, toughness is strengthened, resistance to tensile force is excellent, and durability is increased. We provide waterproof sheets used in various places such as highways, tunnels, building underground parking lots, and building rooftops at a much lower cost, minimizing the indiscriminate incineration of used diapers and contributing to saving resources and preserving the environment. It is possible to provide waterproof sheets made from recycled pulp recovered from .

Figure 1 is a perspective view of a waterproof sheet recycled from pulp recovered from discarded diapers according to the present invention;
Figure 2 is a side cross-sectional view of the waterproof sheet of Figure 1;
Figure 3 is a process flow chart showing a method of manufacturing a waterproof sheet using recycled pulp recovered from discarded diapers according to the present invention;
FIG. 4 is a diagram illustrating an example of a process system for performing the method of manufacturing the waterproof sheet of FIG. 3.

Hereinafter, the present invention will be described in detail. The embodiments and drawings introduced below are provided as examples so that the idea of the present invention can be sufficiently conveyed to those skilled in the art. In addition, if there is no other definition in the technical and scientific terms used in the present invention, they have the meanings commonly understood by those skilled in the art in the technical field to which this invention pertains, and the present invention is described in the following description and accompanying drawings. Descriptions of known functions and configurations that may unnecessarily obscure the gist of are omitted.

Hereinafter, the present invention will be described in detail with reference to the attached drawings.

The attached drawings are merely an example to explain the technical idea of the present invention in more detail, and therefore the technical idea of the present invention is not limited to the form of the attached drawings.

As shown in Figures 1 and 2, the waterproof sheet 100 made of recycled pulp recovered from discarded diapers according to the present invention includes a base layer 110 made of a synthetic resin material provided to form a planar structure, and a base layer ( 110), an upper reinforcement layer 120 provided on the upper part of the base layer 110, a lower reinforcement layer 130 provided on the lower part of the base layer 110, and an upper reinforcement layer 120 and a lower reinforcement layer 130, respectively. Includes a finishing protective layer 140.

The base layer 110 is made of non-woven fabric.

The base layer 110 according to the present invention preferably uses natural fibers or synthetic fibers in an amount of about 50 to 190 g per hebe (㎡).

This means that if less than 50 g of natural fiber or synthetic fiber is used per hebe of the base layer 110, when the temperature rises to about 70°C during the manufacture of the sheet, the tissue of the non-woven fabric weakens and shrinks due to heat, which may cause wrinkles to form in the sheet. This is because if more than 190 g of natural fiber or synthetic fiber is used per hebe of the base layer 110, the overall strength of the sheet becomes too hard, which may actually interfere with the knockdown of the sheet.

Here, synthetic fibers have excellent heat resistance, weather resistance, and dimensional stability, and have small orientation, showing almost the same physical properties in all directions, so when used in the non-woven fabric of the waterproof sheet 100, simultaneous fracture of the sheet or creep due to continuous tensile force occurs. (creep) The risk of rupture can be reduced.

The upper reinforcement layer 120 and the lower reinforcement layer 130 are characterized by being made of polymer modified asphalt and synthetic resin and pulp obtained by crushing the shell portion of the waste diaper 5.

Accordingly, by applying the synthetic resin and pulp recovered from the waste diaper 5 to the waterproof sheet 100, the pulp component improves heat resistance, minimizes thermal deformation, strengthens toughness, and provides excellent resistance to tensile force. Durability can be increased, and waterproof sheets (100), which are used in various places such as highways, tunnels, building underground parking lots, and building rooftops, are provided at a much lower cost to minimize indiscriminate incineration of waste diapers (5) and save resources. It is possible to provide a waterproof sheet (100) made by recycling pulp recovered from discarded diapers, which can contribute to environmental conservation.

Here, of course, instead of polymer modified asphalt, improved asphalt in the form of small particles with improved temperature sensitivity or viscoelastic properties of petroleum asphalt (straight asphalt) can be used by mixing rubber (SBS) with petroleum asphalt (straight asphalt).

More specifically, the upper reinforcement layer 120 and the lower reinforcement layer 130 are made of a material obtained by melting and mixing 50% by weight of polymer modified asphalt with 50% by weight of synthetic resin and pulp obtained by crushing the shell portion of the waste diaper 5. It is preferable that the layers are stacked on top and bottom of the layer 110.

At this time, the pulp component that goes into the material forming the upper reinforcing layer 120 and the lower reinforcing layer 130 is most of the pulp inside the shell portion of the waste diaper 5 (35 to 40 weight of the total weight of the waste diaper 5). It is preferable that it is a pulp component that remains together with the shell portion of the waste diaper 5 after scraping off (corresponding to about %).

Accordingly, by applying the synthetic resin and pulp recovered from the waste diaper 5 to the waterproof sheet 100, the fibrous pulp component firmly holds it within the tissues of the upper reinforcing layer 120 and the lower reinforcing layer 130. This improves heat resistance, minimizes thermal deformation, enhances toughness, improves resistance to tensile force, and increases durability.

That is, the upper reinforcement layer 120 and the lower reinforcement layer 130 are applied to have a certain thickness by spraying a liquid material obtained by melting and mixing improved asphalt, synthetic resin, and pulp together on the upper and lower surfaces of the base layer 110 using a nozzle, etc. is formed

In one embodiment of the present invention, the synthetic resin component of the upper reinforcing layer 120 and the lower reinforcing layer 130 includes polyethylene (PE) and polypropylene (PP) obtained by crushing the shell portion of the waste diaper 5, and the upper The pulp component of the reinforcing layer 120 and the lower reinforcing layer 130 preferably includes 10 to 20% by weight of pulp remaining by hot melt fusion even after crushing the shell portion of the waste diaper 5.

Accordingly, in the past, it was almost impossible to add the pulp component even if an attempt was made to mix the pulp component with the synthetic resin component due to the difference in specific gravity between the synthetic resin component and the pulp component. However, according to the present invention, during the recycling process of the waste diaper 5, the synthetic resin is added. The manufacturing process becomes easy because the pulp component that remains fixed to the shell portion of the component can be mixed together with the modified asphalt and used as the upper reinforcing layer 120 and the lower reinforcing layer 130, and the pulp component provides heat resistance. With this improvement, thermal deformation is minimized and toughness is strengthened, resulting in excellent resistance to tensile force and increased durability. Waterproofing sheet (100), which is used in various places such as highways, tunnels, building underground parking lots, and building rooftops, is much cheaper. It can be provided at a cost to minimize indiscriminate incineration of waste diapers (5) and contribute to saving resources and preserving the environment.

As shown in FIGS. 1 and 2, the finishing protective layer 140 is formed after the upper reinforcing layer 120 and lower reinforcing layer 130 are formed on the top and bottom of the base layer 110, and then they are attached to another place or rolled up. It is provided with vinyl or PE film to prevent mutual adhesion, and is provided to surround and protect the upper reinforcing layer 120 and the lower reinforcing layer 130.

Accordingly, the waterproof sheet 100 according to the present invention can be wound to a certain length (for example, approximately 50 to 100 m) to be safely protected and transported so that it can be conveniently used in the field, and can be used in tunnels, building rooftops, and buildings. At a construction site such as an underground parking lot, the waterproof sheet 100 can be easily and conveniently attached to the construction site by applying heat while unwinding the rolled waterproof sheet 100.

Meanwhile, the method of manufacturing the waterproof sheet 100 according to the present invention, as shown in FIG. 3, includes a shredding step (S10) in which a large amount of waste diapers 5 are shredded and transported in a shredder 10, and During the process of further grinding and pulverizing the pieces shredded in the crushing step (S10) in the grinder (20, 30), a large amount of pulp component in the form of fiber and a synthetic resin component are separated using the difference in gravity, respectively, and a small amount of pulp along with the synthetic resin component are separated. A crushing and separation step (S20) in which only the components are recovered separately, and a melt mixing process at high temperature of synthetic resin and pulp obtained by crushing the shell portion of the waste diaper 5 recovered through the crushing and separation step (S20) and improved asphalt. The reinforcing material melt mixing step (S30) and the liquid material obtained through the reinforcing material melt mixing step (S30) are sprayed and applied to the upper and lower surfaces of the base layer 110 to form the upper reinforcing layer 120 and the lower reinforcing layer 130. A reinforcing layer stacking step (S40) and a finishing protective layer attaching step ( S50).

In the crushing step (S10), as shown in FIG. 4, a large amount of waste diapers 5 are washed and then transported along a transfer conveyor inclined toward the shredder 10, thereby crushing a large amount of waste diapers 5. It includes the step of allowing them to be crushed by a crushing cutter rotated inside the crusher (10).

As an embodiment of the present invention, it is preferable that the waste diapers 5 shredded in the shredding step (S10) are shredded to a size of approximately 10 to 100 mm.

In the crushing separation step (S20), the waste diaper pieces shredded in the crusher 10 are transferred to the crushers 20 and 30 and further crushed to a powder state by a crushing cutter rotating inside the crushers 20 and 30. When the pulp component of the pulverized fine pieces sinks under its own weight, it is sucked from the bottom by vacuum suction and transferred to be stored in the pulp storage tank 40, and synthetic resin components such as PP (polypropylene) and PE (polyethylene) These include the step of being captured as they are blown upward during pulverization and transferred to be stored separately in a synthetic resin storage tank 50 along with a small amount of pulp components.

In one embodiment of the present invention, it is preferable that the pulp component of the fine pieces of waste diapers pulverized in the pulverization and separation step (S20) is pulverized into fibers with a size of approximately 1 to 5 mm.

In addition, as shown in FIG. 4, the grinding and separation step (S20) is preferably performed continuously in two or more steps.

Accordingly, by performing the grinding separation step (S20) in two or more multi-stage continuous processes, grinding is performed continuously several times, and finer and finer particle pulp components with excellent processability are recovered for reuse. It can be done as much as possible.

That is, as an embodiment of the present invention, as shown in FIG. 4, in the crushing and separation step (S20), the waste diaper pieces shredded in the crusher 10 are transferred to the first crusher 20 and primarily crushed. After the pulverized pulp components are stored in the pulp storage tank 40, the remaining fine pieces that fly upward without being classified as pulp components in the first crusher 20 are transferred back to the second crusher 30. The secondarily pulverized and finally pulverized pulp components are further stored in the pulp storage tank 40, and the remaining synthetic resin components that are blown upward without being classified as pulp components in the second pulverizer 30 are stored in the synthetic resin storage tank ( It is desirable to transport it to 50) and store it.

Accordingly, the waste diaper 5 is pulverized and crushed through the crushing step (S10) and the crushing separation step (S20), thereby removing the pulp component inside the shell portion of the synthetic resin component such as PP and PE in the waste diaper 5. Only these (corresponding to about 35 to 40% by weight of the total weight of the waste diaper 5) can be recovered as cleanly as possible.

At this time, 6 to 8% by weight of SAM (Super Absorbent Material), which is a super absorbent material originally included in the pulp component of the waste diaper 5, is also recovered along with the pulp components. Meanwhile, about 1 to 2% by weight of yarn remains in the shell portion of the waste diaper 5 used in the waterproof sheet 100 according to the present invention, and is recovered along with the synthetic resin component and pulp component.

Accordingly, by using the synthetic resin and a small amount of recycled pulp recovered from the waste diaper 5 in the waterproof sheet 100, moisture absorption performance can be added to the waterproof sheet 100, thereby further improving durability.

The reinforcing material melt mixing step (S30) includes melt mixing the synthetic resin stored in the synthetic resin storage tank 50 and a small amount of remaining pulp components with improved asphalt particles at high temperature.

Since the subsequent steps are the same as those mentioned above, detailed description will be omitted.

Although the technical aspect has been described above and in the accompanying drawings, the technical idea of the present invention is for explanation purposes only and is not intended to be limiting, and those skilled in the art will understand the present invention. It will be understood that various modifications and changes can be made to the technical idea of the present invention without departing from the technical scope described in the claims, which will be described later.

10: crusher 20: first crusher
30: second crusher 40: pulp storage tank
50: synthetic resin storage tank 100: waterproof sheet
110: base layer 120: upper reinforcement layer
130: lower reinforcement layer 140: finishing protective layer

Claims (3)

A base layer 110 made of synthetic resin provided to form a planar structure;
an upper reinforcement layer 120 provided on the base layer 110;
a lower reinforcement layer 130 provided below the base layer 110; and
A finishing protective layer 140 provided on the upper part of the upper reinforcement layer 120 and the lower part of the lower reinforcement layer 130;
Includes,
The base layer 110 is made of non-woven fabric,
The upper reinforcement layer 120 and the lower reinforcement layer 130 are made of polymer modified asphalt and synthetic resin and pulp obtained by crushing the shell portion of the waste diaper 5,
The upper reinforcing layer 120 and the lower reinforcing layer 130 are materials obtained by melting and mixing 50 wt% of polymer modified asphalt with 50 wt% of synthetic resin and pulp obtained by crushing the shell portion of the waste diaper 5, and the base layer ( 110) is provided to be stacked above and below,
The synthetic resin component of the upper reinforcing layer 120 and the lower reinforcing layer 130 includes polyethylene (PE) and polypropylene (PP) obtained by crushing the shell portion of the waste diaper 5,
The pulp component of the upper reinforcing layer 120 and the lower reinforcing layer 130 includes 10 to 20% by weight of pulp remaining by hot melt fusion even after crushing the shell portion of the waste diaper 5,
The base layer 110 uses 50 to 190 g of natural fiber or synthetic fiber per hebe (㎡),
The pulp component that goes into the material forming the upper reinforcing layer 120 and the lower reinforcing layer 130 is the pulp inside the shell portion of the waste diaper 5 (corresponding to 35 to 40% by weight of the total weight of the waste diaper 5) ) is a pulp component that remains along with the shell portion of the waste diaper (5) after scraping off the
6 to 8% by weight of SAM (Super Absorbent Material), which is a super absorbent material originally included in the pulp component of the waste diaper (5), is also recovered along with the pulp components, and the Sam is in the shell portion of the waste diaper (5). A waterproof sheet made from recycled pulp recovered from discarded diapers, which remains at 1 to 2% by weight and is recovered and used together with synthetic resin components and pulp components.

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